EP0186068A1 - Circuit arrangement for the production of channel carrier frequencies, pilot auxiliary frequencies, system carrier frequencies and control frequencies for a carrier system in a multichannel carrier current telephone system with pre-modulation - Google Patents

Abstract

The circuit comprises a basic oscillator, a combination of frequency dividers connected at the output of the basic oscillator, amplifiers connected at the output of the frequency dividers, or a filter connected at the output of said dividers, also modulators connected at the output of the amplifiers or a modulator connected to the filters and filters connected at the output of the modulators as well as channel carrier frequency outputs.

Description

The invention relates to a circuit arrangement for the generation of channel carrier frequencies, pilot auxiliary frequencies, system carrier frequencies and control frequencies for system carrier vielkanälige carrier current telephone with _a PPENDICES Vormodulationssystem.

As is known, the channel modulation cascades require a large number of carrier frequencies with high signal purity and great accuracy. To form a 12-channel basic group, together with the pre-modulation carrier frequency, thirteen different carrier frequencies are required.

As is known, the modulation in the formation of the basic group with pre-modulation system has two stages. First, all channels are modulated with the pre-modulation carrier frequency, then the one sideband is filtered out using a channel filter.Then modulating the sidebands of each channel with different channel carrier frequencies results in the 12-channel basic group corresponding to the recommendations of the CCITT, the one Ranges from 60 to 108 kHz. The unnecessary sideband resulting from the second modulation is cut off by means of a group filter. The basic group has an inverted position, which means that the zero frequency of the first channel drops to 108 kHz, while the zero frequency of the other channels properly drops to 104, 100 ... 64 kHz. In other words, the largest channel carrier frequency belongs to the 1st channel of the basic group.

In the systems, the element with the largest number is the channel unit with the transmission and reception-oriented channel band filter.

In the systems with a pre-modulation system, each channel band filter can have the same design, and consequently the channel units can also have the same design. This fact has a significant economic impact, since it enables the duct units of the systems with small and large number of ducts to be designed in the same way, the number of production pieces increases, maintenance becomes easier, etc.

However, the price of the uniform, inexpensive channel units and the relatively more complicated carrier generation are still much more economical with the pre-modulation system than with the pre-group or with the direct modulation system.

As is known, the circuits for generating the carrier frequencies for carrier current systems consist of highly stable oscillators, frequency multipliers (harmonic generators), frequency dividers, modulators, filters and amplifiers.

These circuits are not equally applicable to modern assembly technologies. The frequency dividers are easiest to use and they are also the cheapest. The manufacture of the thermostats and filters is complicated, time-consuming and costly. Therefore, there is the Be in the modern devices strive to reduce the number of thermostats and filters, or primarily to use the other integrable elements, such as frequency dividers, amplifiers.

Furthermore, the known and the inventive circuit arrangement, which are compared in the following, the amplifiers located at the end of the chains are not considered as a system feature and their representation is disregarded.

The frequencies to be generated are - due to the 4 kHz channel division - a multiple of 4 kHz. An exception is the only system carrier frequency that cannot be generated immediately starting from 4 kHz.

The essence of the generally used circuit arrangement for generating the multiples of 4 kHz is that the required frequencies are selected via a bandpass filter which is connected to the output of an even and odd harmonic generator of 4 kHz. The selected frequencies should be amplified. This solution, as is generally known, has the disadvantage that a large number of bandpass filters with strict parameters are required, which complicates the manufacture and results in high costs.

The essence of the known solution shown in FIG. 2 is similar to that shown in FIG. 1 in that it is also designed with filters that follow the harmonic generator. The difference of this solution to that shown in FIG. 1 is that the control frequency is a multiple of 4 kHz, so that the interference components in the output spectrum are further away. This makes it possible to reduce the number of filter elements.

Both in the circuit arrangement shown in FIG. 1 and in the circuit arrangement shown in FIG the separation of the output of the even harmonics and the odd harmonics saves filter elements.

A disadvantage of the circuit arrangement shown in FIG. 2, however, is that only twice of certain frequencies occur in the spectrum, so that a subsequent frequency division is required to generate these frequencies. In both previous circuit arrangements, an accident can only be caused by an error in the oscillator or the harmonic generator. A fault in the filters located at the end of the chains (or the amplifiers, not shown) only leads to a partial breakdown, the faulty circuit parts can be removed without affecting the function of the other parts. The system is "radial".

There is also a solution in which the required frequencies are generated by means of PLL (phase synchronization loop) circuits. This system is also frequency rigid. The accuracy of the output frequencies depends on the accuracy of the control frequency, which is an advantage of the system. A disadvantage of this system is that a PLL circuit is required to generate each frequency, in which the voltage-controlled oscillators VCO have to operate at a frequency of 5 ... 10 MHz due to their Varicap tunability. Because of the risk of cross-talk, this can only be achieved in separate, shielded circuit units. The output frequencies are obtained after frequency division. In the case of the PLL circuits, care must be taken to ensure that if the control frequency is not present, no faulty frequency is output from the voltage-controlled oscillator VCO, which is then free-running.

The aim of the invention is to eliminate the drawbacks mentioned above.

The invention is based on the knowledge that the The simplest and most economical solution is to derive each frequency from the signal of a single oscillator. Then the frequency of the oscillator is the smallest common multiple of the required frequencies. Due to the large number of frequencies, however, this would result in an unrealizable frequency. To avoid this, a compromise is proposed that an oscillator frequency is selected from which at least a part of the required frequencies can be obtained by integer division and from the already divided frequencies and frequencies obtained by further division, the missing frequencies are generated by modulation in this way that the number of modulators and filters used remains minimal.

The circuit arrangements in FIGS. 3, 4, 5 and 6 show solutions which are based on the above finding.

The circuit arrangement according to the invention offers a solution for uniform carrier frequency generation for a uniform channel modulation system. The circuit arrangements which can be embodied according to the invention are variants of the basic arrangement according to the invention which, depending on the number of channels or depending on the demands on the control frequency of the corresponding overhead line or cable system, can be designed differently (FIGS. 3, 4, 5, 6). Of the other frequencies which are required for the functioning of the systems provided with the circuit arrangement according to the invention, the invention relates to the generation of a system carrier frequency, two pilot auxiliary frequencies required for pilot reception, and some system carrier control frequencies.

The advantage is that the divided frequencies can theoretically only contain their own harmonics and other foreign frequencies cannot, and can therefore be used immediately after sinusoidal shaping. The pre-modulate de Channel carrier frequency F _E can be selected, for example, at 24 kHz.

The circuit arrangement according to the invention has the advantages of the earlier known circuit arrangements, namely the control with a single oscillator, the "radial" arrangement.

Another advantage of the invention is that the filters are simple because they only have to suppress the side frequency, which is not sent, and the carrier leakage current. The modulators can be assembled with the filters. In the circuit arrangements, any modulator or output can be omitted - according to the current structure - without disturbing the function of the other circuit parts.

In the circuit arrangements according to the invention, a small number of auxiliary frequencies are also permitted which do not leave the system, but which are advantageously required for generating the output frequencies.

The invention is explained in more detail below on the basis of preferred exemplary embodiments with reference to the attached drawing.

• Fig. l eine ansich bekannte Schaltungsanordnung, die mit einem harmonischen Generator zur Erzeugung der Vielfachen von 4 kHz und Bandfiltern versehen ist,
• Fig. 2 eine weiterentwickelte Variante der Schaltungsanordnung gemäss Fig. 1,
• Fig. 3 ein Blockschema der erfindungsgemässen Schaltungsanordnung die die einem Vielfachen von 4 kHz entsprechenden Frequenzen ausschliesslich durch Fre- .quenzteilung und Modulation erzeugt,
• Fig. 4 eine weiterentwickelte Ausführungsform der erfindungsgemässen Schaltungsanordnung gemäss Fig. 3, bei der ähnlicherweise die Vielfachen der Frequenz von 4 kHz durch Frequenzteilung und durch Modulation erzeugt werden, sowie weiterhin weitere zwei Steuerfrequenzen erzeugt werden,
• Fig. 5 eine weiterentwickelte Ausführungsform der Schaltungsanordnung gemäss Fig. 4, die davon ebweichend zwei Signale, d.h. eine Steuerfrequenz und ein Pilotsignal erzeugt,
• Fig. 6 eine vereinfachte Variante der Schaltungsanordnung gemäss Fig. 4, wobei alle Frequenzen entweder durch Teilung oder durch Teilung und Mpdulation erzeugt werden.

Show it:

• 1 is a circuit arrangement which is known per se and which is provided with a harmonic generator for generating multiples of 4 kHz and band filters,
• 2 shows a further developed variant of the circuit arrangement according to FIG. 1,
• 3 shows a block diagram of the circuit arrangement according to the invention which generates the frequencies corresponding to a multiple of 4 kHz exclusively by frequency division and modulation,
• FIG. 4 shows a further developed embodiment of the circuit arrangement according to the invention according to FIG. 3, in which the multiples of the frequency of 4 kHz are similarly generated by frequency division and by modulation, and further two Control frequencies are generated
• 5 shows a further developed embodiment of the circuit arrangement according to FIG. 4, which also generates two signals, ie a control frequency and a pilot signal,
• 6 shows a simplified variant of the circuit arrangement according to FIG. 4, all frequencies being generated either by division or by division and modulation.

The fact that most of the frequencies represent a multiple of 4 kHz makes the use of a frequency-multiplying harmonic generator and the selection of the required frequencies obvious by means of filters. Such a circuit arrangement is shown in Fig. 1. Filters SZ1, SZ2,... SZ12 are connected to a 2n × 4 kHz even output of a harmonic generator HG which contains even harmonics, while the odd output (2n-1). Connect 4 kHz of the harmonic generator HG filter SZ3 ... SZ13. The advantage of this known solution is that the required frequency accuracy and stability can easily be ensured due to the single oscillator. The disadvantage of this solution is that in order to generate the thirteen frequencies in a correspondingly pure manner, thirteen complicated filters are required, despite the separation of even and odd outputs of the harmonic generator. The filters must not load the spectrum on the frequency of the other filters, ie they must be switchable in parallel. The known solution shown in Fig. 2 is an improved version. With this arrangement, a double, 8 kHz spectrum of the harmonic generator is assumed - due to the simplification of the filters. As a result, there are frequencies of which there are only two in the spectrum, so after filtering out the frequencies there is still a 2: 1 Frequency division required (in the figure for the frequencies ^F C1, ^F C3, ^F _{C5 '} F _C7 , ^F C9 and F _C11 ) · In this solution, the number of filters is also thirteen.

3 is used to generate channel carrier frequencies and pilot auxiliary frequencies for multi-channel carrier current telephoto layers with pre-modulation system. An output of a basic oscillator 0 is connected on the one hand to the input of a frequency divider D1 with a divider ratio of 20: 1 and on the other hand to an input of a frequency divider D10 with a divider ratio of 21: 1. The output of the frequency divider Dl branches in three directions, namely with the input of a frequency divider D2 with a division ratio of 7: 1, with the input of a frequency divider D4 with a division ratio of 6: 1 and with the input of a frequency divider D8 a divider ratio of 2: 1. The output of the frequency divider D10 is connected to the input of the frequency divider D6 with a division ratio of 32: 1, to the input of the frequency divider D7 with a division ratio of 5: 1 and to the input of the frequency divider D9 with a division ratio of 8: 1. The output of the frequency divider D2 is connected to the input of a frequency divider D3 with a division ratio of 4: 1 and to the input of an amplifier E2. The output of the frequency divider D4 is connected to the input of a frequency divider D5 with a division ratio of 4: 1 and to the input of an amplifier E3. The output of the frequency divider D6 is applied to the input of an amplifier E4. The frequency divider D7 is connected to the input of an amplifier E6. The output of the frequency divider D8 is connected to a pilot auxiliary frequency output P _S1 and an input b of a modulator M ₁₀ . The output of the frequency divider D9 is connected to the input of a filter SZ10, the output of which is connected to an input a of the nodulator M10 is connected. An output of a filter SZ11 connected to the output of the modulator MI10 is connected to a pilot auxiliary frequency output P _S2 . The output of the frequency divider D5 with a divider ratio of 4: 1 is led to an input of an amplifier E5. The output of the frequency divider D3 with a divider ratio of 4: 1, however, is connected to the input of an amplifier El. The output of the amplifier E 1 branches in four directions: to a pre-modulation carrier frequency output F _E , to an input a of a modulator Ml, to an input a of the modulator M4 and to an input a of the modulator M7. The output of the amplifier E2 also branches in four directions: to a channel carrier frequency output F _C10 , to an input b of a modulator M6, to an input b of a modulator M7 and to an input b of a modulator M8. The output of the amplifier E3 also branches in four directions: to an input b of the modulator M1, an input b of the modulator M2, a channel carrier frequency output F _C6 and an input b of the modulator M9. The output of the amplifier E4 is also branched in four directions: to an input a of a modulator M2, to an input a of a modulator M5, to an input a of a modulator M6 and to an input a of a modulator M9. The output of the amplifier E5 branches in two directions: to an input a of the modulator M3 and to an input a of the modulator M8. The output of the amplifier E6 branches in four directions: to the input b of the modulator M3, an input b of the modulator M4, an input be of the modulator M5 and a channel carrier frequency output F _C2 . An output of a filter SZI following the modulator M1 is a channel carrier frequency output F _C12 , an output of a filter SZ2 following a modulator M ₂ is a channel carrier frequency output F _C11 , an output of a filter SZ3 following the modulator M3 is a channel delay The frequency output F _C9 , an output of a filter SZ4 following the modulator M4 is a channel carrier frequency output F _CB , an output of a filter SZ5 following the modulator M5 is a channel carrier frequency output F _C7 , an output of a filter SZ6 following the modulator M6 is a channel carrier frequency output F _C5 , an output of a filter SZ7 following the modulator M7 is a channel carrier frequency output F _C4 , an output of a filter SZ8 following a modulator M8 is a channel carrier frequency output F _C3 , while an output of a filter SZ9 following the modulator M9 is a channel carrier frequency output F _C1 represents.

The number of characteristic components used in the circuit arrangement according to FIG. 3 is summarized below:

4 illustrates a circuit arrangement according to the invention for generating channel carrier frequencies, pilot auxiliary frequencies and system carrier control frequencies for multichannel carrier current telephone systems with a pre-modulation system.

The output of the basic oscillator 0 is branched in three directions: to a system carrier control frequency output F _V1 , to an input of a frequency divider Dl with a division ratio of 20: 1, and to an input of a frequency divider Dll with a division ratio of 7: 1. The output of the frequency divider Dl with a divider ratio of 20: 1 branches in three directions: to the input of the frequency divider D2 with a division ratio of 7: 1, to the input of the frequency divider D4 with a division ratio of 6: 1 and to the input of the frequency divider D8 with a division ratio of 2: 1. The output of the frequency divider D11 with a division ratio of 7: 1 branches in two directions: to an input of a frequency divider D12 with a division ratio of 3: 1 and to an input of a frequency divider D13 with a division ratio of 16: 1. The output of the frequency divider D12 with a divider ratio of 3: 1 branches in three directions: to the input of the frequency divider D6 with a divider ratio of 32: 1, to the input of the frequency divider D7 with a divider ratio of 5: 1 and to the input of the Frequency divider D9 with a divider ratio of 8: 1. The output of the frequency divider D13 with a divider ratio of 16: 1 is connected to a channel carrier frequency output F _C4 and to an input of a filter SZ12. The output of the filter SZ12 represents a channel carrier control frequency output F _V2 . The output of the frequency divider D2 with a division ratio of 7: 1 is connected to the input of the amplifier E2 and the input of the frequency divider D3 with a division ratio of 4: 1. The output of the frequency divider D3 with a divider ratio of 4: 1 is connected to the input of the amplifier El. The output of the frequency divider D4 with a division ratio of 6: 1 is connected to the input of the amplifier E3 and the input of the frequency divider D5 with a division ratio of 4: 1. The output of the frequency divider D5 with a divider ratio of 4: 1 is applied to the input of the amplifier E5, while the output of the frequency divider D6 with a divider ratio of 32: 1 is connected to the input of the amplifier E4. The output of the frequency divider D7 with a divider ratio of 5: 1 is connected to the input of the amplifier E6. The output of the frequency divider D8 with a divider ratio of 2: 1 is on a pilot auxiliary frequency output P _S1 and to an input b of the modulator MIO. The output of the amplifier E1 branches in three directions: to a pre-modulation carrier frequency output F _E , to the input of the modulator Ml and to the input of the modulator M4. The output of amplifier E2 branches in three directions: to a channel carrier frequency output F _C10 to the input of modulator M6 and to the input of modulator M8. The output of the amplifier E3 branches in four directions: to an input b of a modulator Ml and the modulator M2, to a channel carrier frequency output F _C6 and to the input b of the modulator M9. The output of the amplifier E4 branches in four directions: to the input of the modulators M2, M5, M6 and M9. The output of amplifier E5 is connected to the input of modulators M3 and M8. The output of amplifier E6 is connected to input b of modulators M3, M4 and M5 and to a channel carrier frequency output F _C2 .

The output of the frequency divider D9 with a division ratio of 8: 1 is connected to the input of the filter SZ10, the output of which is connected to the input a of the modulator MIO. The output of a filter SZ11 following the modulator MIO forms a pilot auxiliary frequency output P _S2 . The output of the filter SZ1 connected to the modulator M1 forms a channel carrier frequency output F _C12. The output of the filter SZ2 connected to the modulator M2 forms the channel carrier frequency output F _C11 . The output of the filter SZ3 connected to the modulator M3 forms the channel carrier frequency output F _C9 . The output of the filter SZ4 connected to the modulator M4 forms the channel carrier frequency output F _C8 . The output of the filter SZ5 connected to the modulator M5 forms the channel carrier frequency output FC7. The output of the filter SZ6 connected to the modulator M6 forms the channel carrier frequency output F _C5 . The one with the Filter SZ8 connected to modulator M6 forms the channel carrier frequency output F _C3 . The output of filter Sz9 connected to modulator M9, on the other hand, forms the channel carrier frequency output F _C1 .

Below is an overview of the number of characteristic components used in the inventive bed arrangement according to FIG. 4:

In FIG. 5, an inventive circuit arrangement for the generation of channel carrier frequencies, system carrier frequencies and control system carrier frequencies for vielkanälige carrier flow F _e is rnsprechanlagen with Vormodulationssystem shown. The output of the basic oscillator 0 branches in two directions: to the input of the frequency divider Dl with a division ratio of 20: 1 and to the input of the frequency divider Dll with a division ratio of 7: 1. The output of the frequency divider Dl with a division ratio of 20: 1 is connected to the input of the frequency divider D2 with a division ratio of 7: 1 and the input of the frequency divider D4 with a division ratio of 6: 1, the output of the frequency divider Dll with a division ratio of 7: 1 is connected to the input of the frequency divider D12 with a division ratio of 3: 1 and to the input of the frequency divider D13 with a division ratio of 16: 1. The output of the frequency divider D12 with a division ratio of 3: 1 is connected to the input of the frequency divider D6 with a division ratio of 32: 1 and the input of the frequency divider D7 with a division ratio of 5: 1. The output of the frequency divider D13 is at the channel carrier frequency output P _C4 and at the input of the Fre D14 with a divider ratio of 2: 1 connected. The output of frequency divider D14 with a divider ratio of 2: 1 is connected to the input of amplifier E8, while the output of amplifier E8 is connected to a system carrier control frequency output F _V1 and to the inputs of frequency divider D15 with a divider ratio of 2: 1 and D16 with a division ratio of 5: 1. The output of the frequency divider D2 with a division ratio of 7: 1 is connected to the input of the frequency divider D3 with a division ratio of 4: 1 and the input of the amplifier E2, while the output of the frequency divider D3 with a division ratio of 4: 1 to the Input of the amplifier El is connected. The output of the frequency divider D4 with a division ratio of 6: 1 is connected to the input of the frequency divider D5 with a division ratio of 4: 1. The output of the frequency divider D5 with a divider ratio of 4: 1 is led to the input of the amplifier E5. The output of the frequency divider D7 with a divider ratio of 5: 1 is applied to the input of the amplifier E6. The output of the frequency divider D15 with a divider ratio of 2: 1 is connected to the input of the filter SZ13, the output of which is connected to the input of the modulator Mll, while the output of the modulator Mll is applied to the filter SZ14. The output of the frequency divider D16 with a divider ratio of 5: 1 is connected to the input of the filter SZ15, the output of which is connected to the input of the amplifier E7. The output of the amplifier E7 is connected to the input b of the modulator Mll. The output of filter SZ14 at the same time a system ^{carrier output represents F} _FR. The output of the amplifier El is connected to a pre-modulation carrier frequency output F _E and to the inputs a of the modulators M1 and M4. The output of the amplifier E2 is at the channel carrier frequency output F _CIO and at the inputs b of the modulators M6 and M8 connected. The output of the amplifier E3 is connected to the input b of the modulators M1, M2 and M9 and to the channel carrier frequency output F _C6 . The output of the amplifier E4 is applied to the inputs b of the modulators M2, M5, M6 and M9. The output of the amplifier E5 is connected to the inputs a of the modulators M3 and M8. The output of the amplifier E6 is connected to the inputs b of the modulators M3, M4 and M5 and to the channel carrier frequency output F _C2 . The output of the filter SZ1 following the modulator M1 forms the channel carrier frequency output F _C12 ', while the output of the filter SZ2 following the modulator M2 forms the channel carrier frequency output F _C11 ' the output of the filter SZ3 following the modulator M3 forms the channel carrier frequency output F _C9 , which Output of the filter SZ4 following the modulator M4, the channel carrier frequency output F _C8 , the output of the filter SZ5 following the modulator M5, the channel frequency carrier output F _C7 , the output of the filter SZ6 following the modulator M6, the channel carrier frequency output F _C5 , the output of the modulator M7 connecting filter SZ7 form the channel carrier frequency output F _C3 and the output of the filter SZ9 connecting the modulator M9 form the channel carrier frequency output F _C1 .

An overview of the number of characteristic components used in the inventive circuit arrangement according to FIG. 5 is given below:

6 is a circuit arrangement according to the invention shown for the generation of channel carrier frequencies and system carrier control frequencies for carrier current telephone systems with pre-modulation system. The output of the basic oscillator 0 branches in two directions: to the frequency divider Dl with a division ratio of 20: 1 and to the frequency divider Dll with a division ratio of 7: 1. The output of the frequency divider Dl with a divider ratio of 20: 1 is connected to the inputs of the frequency divider D4 with a divider ratio of 6: 1 and D2 with a divider ratio of 7: 1. The output of the frequency divider D4 with a divider ratio of 6: 1 simultaneously forms the channel carrier frequency output F _C6 . The output of the frequency divider D2 with a division ratio of 7: 1 is connected to the input of the amplifier E2 and the input of the frequency divider D3 with a division ratio of 4: 1. The output of the frequency divider D3 with a divider ratio of 4: 1 forms the system carrier control output F _V3 on the one hand and is connected to the input of the amplifier El on the other hand. The output of the amplifier El forms the pre-modulation carrier frequency output F _E , while the output of the amplifier E2 is led to the input b of the modulator M6. The output of the frequency divider Dll with a division ratio of 7: 1 is connected to the input of the frequency divider D12 with a division ratio of 3: 1 and the input of the frequency divider D13 with a division ratio of 16: 1. The output of the frequency divider D13 with a divider ratio of 16: 1 forms on the one hand the channel carrier frequency output F _C4 and on the other hand is connected to the input of the filter SZ12. The output of the filter SZ12 forms the system carrier control frequency output F _Vl . The frequency divider D12 with a division ratio of 3: 1 is followed by the input of the frequency divider D6 with a division ratio of 32: 1 and the input of the frequency divider D17 with a division ratio of 4: 1. The output of the frequency divider D6 with one Divider ratio of 32: 1 is connected to the input of amplifier E4, the output of which is connected to the input of modulator M6. The output of the frequency divider D17 with a divider ratio of 4: 1 forms the system carrier control frequency output F _V2 . The output of the modulator M6 is led to the filter SZ6, the output of which forms the _channel t _r äg _erfre qu _e nz Output F _C5 .

An overview of the number of characteristic components used in the inventive circuit arrangement according to FIG. 6 is given below:

The circuit arrangements according to the invention are repeatedly constructed from the same components. One basic oscillator with thermostat is used for each system, so the accuracy of each output frequency corresponds to the accuracy of the frequency of the basic oscillator. The system carrier control frequency outputs enable the accuracy of the system carrier frequencies to also correspond to the accuracy of the frequency of the basic oscillator. The frequency dividers can be designed as monolithic integrated circuits, or these parts of the circuits can also be implemented using MSI technology. The use of the relatively small number of carrier filters and modulators takes up only a small part of the assembly work of the large number of channel units with LC filters.

A summary of the number of components belonging to the individual figures and the output frequencies is given below:

The solutions shown in FIGS. 3 to 6 are circuit arrangements according to the invention. Of particular importance is e.g. 6 that only a single modulator filter and a separate filter are required to generate seven output frequencies. The circuit arrangement shown in FIG. 6 illustrates the carrier frequency generation for a 3-channel overhead line system, the costs falling on one channel being relatively greatest due to the other common circuit parts. It can be seen from the above that the generation of the carrier frequency is the cheapest in the circuit arrangement according to the invention.

Claims (8)

1.Circuit arrangement for generating channel carrier frequencies and pilot auxiliary frequencies for multichannel carrier current telephone systems with pre-modulation system, which with a basic oscillator, another combination of frequency dividers connected to another output, amplifiers connected to the output of the frequency dividers or filters connected to the output of the frequency divider, and further to the The output of the amplifiers connected modulators or the modulator connected to the filters and the modulators connected to the output of the filters, as well as channel carrier frequency outputs, is characterized in that at least two frequency dividers (D1-D10) connect directly to the single basic oscillator (0), furthermore from the frequency outputs the circuit arrangement has at least five frequency from ^g än ^g e (P _S1, FC2, F _{C6 'F C10,} F ₂₎ directly or via an amplifier (El, E2, E3, E6) to a respective frequency divider (D3, D2, D4, D6 , D5, D7, D8) connected are loose. 2. Circuit arrangement according to claim 1, characterized in that two frequency dividers (D1, D10) are connected to the output of the basic oscillator (0), of which the output of a frequency divider (D1) nit branches in three directions with a division ratio of 20: 1 is: to the input of a frequency divider (D2) with a division ratio of 7: 1, to the input of a frequency divider (D4) with a division ratio of 6: 1 and to the input of a frequency divider (D8) with a division ratio of 2: 1, while the output of the other frequency divider (D10) with a division ratio of 21: 1 also branches in three directions: to the input of a frequency divider (D6) with a division ratio of 32: 1, to the input of a frequency divider (D7) with a division ratio of 5: 1 and at the input of a frequency divider (J9) with a part ratio of 8: 1, that the output of the frequency divider (D2) with a division ratio of 7: 1 is still connected to the input of the frequency divider (D3) with a division ratio of 4: 1, and to the input of the amplifier (E2), while the output of the frequency divider (D4) with a division ratio of 6: 1 is applied to the input of the frequency divider (D5) with a division ratio of 4: 1 and to the input of the amplifier (E3), furthermore the output of the frequency divider (D6) with a division ratio of 32: 1 to the input of the amplifier (E4), the frequency divider (D7) with a division ratio of 5: 1 are connected to the input of the amplifier (E6), while the output of the frequency divider (D8) with a division ratio of 2: 1 forms a pilot auxiliary frequency output (PS1) and is connected to an input (b) of the modulator (MIO), furthermore the output of the frequency divider (D9) with a division ratio of 8: 1 to the input of the filter (SZ10) the output of which is connected to the other input (a) of the modulator (MIO), that the output of the modulator (MIO) is connected to an input of the filter (SZ11), the output of which forms a pilot auxiliary frequency output (PSZ), and the output of the frequency divider (D5) with a divider ratio of 4: 1 connected to the input of the amplifier (El). whose output branches in four directions: to a pre-modulation carrier frequency output (F _E ), to the input (a) of the modulator (M1), to an input (a) of the modulator (M4) and to an input (a) of the modulator ( M7) that the output of the amplifier (E2) branches in four directions: to a channel carrier frequency output (F _C10) , to an input (b) of the modulator (M6), to an input (b) of the modulator (M7) and an input (b) of the modulator (M8) that furthermore the output of the amplifier (E3) is branched in four directions: to an input (b) of the modulator (M1), to an input (b) of the modulator (M2), to a sewer frequency output (F _C6 ) and to an input (b) of the modulator (M9), that the output of the amplifier (E4) continues to branch in four directions: to an input (a) of the modulator (M2), to an input (a ) of the modulator (M5), to an input (a) of the modulator (M6) and to an input (a) of the modulator (M9), furthermore the output of the amplifier (E5) on the one hand with the input (a) of the modulator (M3 ) and on the other hand is connected to the input (a) of the modulator (M8), while the output of the amplifier (E6) branches in four directions: to the input (b) of the modulator (M3), to the input (b) of the Modulator (M4), to the input (b) of the modulator (M5) and to a channel carrier frequency output (F _C2 ), that the output of the filter (SZ1) following the modulator (ML) forms a channel carrier frequency output (F _C12 ), during the Output of a filter (SZ2) following the modulator (M2) forms a channel carrier frequency output (F _C11 ) that w Furthermore, the output of a filter (SZ3) following the modulator (M3) has a channel carrier frequency output (F _C9 ), the output of a filter (SZ4) following the modulator (M4) has a channel carrier frequency output (F _C8 ), the output of a channel following the modulator (M5 ) connecting filter (SZ5) a channel carrier frequency output (F _C7 ), the output of a filter (SZ6) connecting the modulator (M6) a channel carrier frequency output (F _C5 ), the output of a filter connecting the modulator (M7) a channel carrier frequency output (F _C4 ), the output of a filter (SZ8) following the modulator (M8) forms a channel carrier frequency output (F _C3 ), and the output of a filter (SZ9) following the modulator (M9) forms a channel carrier frequency output (F _C1 ). 3. Circuit arrangement for generating channel carrier frequencies, pilot auxiliary frequencies and system carrier control frequencies for multichannel carrier Strora telephone systems with a pre-modulation system, a basic oscillator, a combination of frequency dividers following the output of the basic oscillator, amplifiers connected to the output of the frequency dividers or filters connected to the output of the frequency dividers, modulators connected to the output of the amplifiers or modulators connected to the filters, and so on the output of the modulators connected to filters as well as channel carrier frequency outputs and control frequency outputs, characterized in that at least two frequency dividers (Dl, Dll) are directly connected to the single basic oscillator (0), that at least seven frequency outputs (F _E , F _C2 , F _{C4 '} F _C6' F _{CIO '} F _V2' P _S1 ) directly or via an amplifier (El, E2, E3, E6), possibly via a filter (SZ12) to the frequency dividers (D3, D2, D4, D13 , D7, D8, D16) are connected. 4. Circuit arrangement according to claim 3, characterized in that the output of the basic oscillator (0) branches in three directions: to a system carrier control frequency output (F _V1 ), to the input of the frequency divider (Dl) with a division ratio of 20: 1, as well as to the input of the frequency divider (DLL) having a dividing ratio of 7: 1, the output of the frequency divider (D1) further having a dividing ratio of 20: 1 ver in three directions _- is branches: at the input of the frequency divider (D2) with a Divider ratio of 7: 1, to the input of the frequency divider (D4) with a divider ratio of 6: 1 and to the input of the frequency divider (D8) with a divider ratio of 2: 1, while the output of the frequency divider (Dll) with a divider ratio of 7: 1 branches in two directions: to the input of the frequency divider (D12) with a division ratio of 3: 1 and to the input of the frequency divider (D13) with a division ratio of 16: 1, furthermore the off frequency divider (D12) with a part 3: 1 ratio with the input of the frequency divider (D6) with a divider ratio of 32: 1, the input of the frequency divider (D7) with a divider ratio of 5: 1 and the input of the frequency divider (D9) with a divider ratio of 8: 1 connected that the output of the frequency divider (D13) with a division ratio of 16: 1 forms the channel carrier frequency output (F _C4 ) and is applied to the input of the filter (SZ12), the output of which forms the system carrier control frequency output (FV ₂ ), that the output of the frequency divider (D2) with a division ratio of 7: 1 is connected to the input of the amplifier (E2) and the input of the frequency divider (D3) with a division ratio of 4: 1, the output of which is connected to the input of the amplifier ( El) is guided, furthermore the output of the frequency divider (D4) with a division ratio of 6: 1 to the input of the amplifier (E3) and to the input of the frequency divider (D5) with a division ratio of 4: 1 a is connected, while the output of the frequency divider (D5) is connected with a divider ratio of 4: 1 to the input of the amplifier (E5), that the output of the frequency divider (D6) with a divider ratio of 32: 1 is connected to the input of the amplifier (E4) is connected, furthermore the output of the frequency divider (D7) with a division ratio of 5: 1 to the input of the amplifier (E6), the output of the frequency divider (D8) with a division ratio of 2: 1 to the pilot auxiliary frequency output (P _S1 ) and connected to the input of the modulator (MIO), that the output of the amplifier (El) continues to branch in three directions: to the pre-modulation carrier frequency output (F _E ) and to the inputs (a) of the modulators (Ml, M4), while the output of the amplifier (E2) is connected to the channel carrier frequency output (F _CIO ) and to the inputs (b) of the modulators (M6, M8), furthermore the output of the amplifier (E3) to the channel carrier frequency output (F _C6 ), to the inputs (b). the modulators (M1, M2) and to the input (b) of the modulator (M9), while the output of the amplifier (E4) is connected to the inputs (a) of the modulators (M2, M5, M6, M9), that the output of the amplifier (E5) at the inputs (a) of the modulators (M3, M8), the output of the amplifier (E6) at the inputs (b) of the modulators (M3, M4, M5) and at the channel carrier frequency output ( F _C2 ) are connected, furthermore the output of the frequency divider (D9) with a division ratio of 8: 1 is connected to the input of the filter (SZ10), the output of which is connected to the input (a) of the modulator (M10) during the Output of the filter (SZ11) following the modulator (MZ11) forms the pilot auxiliary frequency output (P _SZ ), so that the output of the filter (SZ1) following the modulator (Ml) continues to form the channel carrier frequency output (F _C12 ), the output of the modulator (M2) connecting filter (SZ2) the channel carrier frequency output (F _{C1 1} ), the output of the filter (SZ3) connecting the modulator (M3) the channel carrier frequency output (F _C9 ), the output of the filter (SZ4) connecting the modulator (M4) the channel carrier frequency output (F _C8 ), the output of the Filter (SZ5) connecting the modulator (MZ5) the channel carrier frequency output (F _C7 ), the output of the filter (SZ6) following the modulator (M6) the channel carrier frequency output (F _C5 ) the output of the filter (SZ8) following the modulator (M8) the channel carrier frequency output (F _C3 ) and the output of the filter (SZ9) following the modulator (M9) form the channel carrier frequency output (FC1). 5. Circuit arrangement for the generation of channel carrier frequencies, system carrier control frequencies and system carrier frequencies for multichannel carrier current telephone systems with pre-modulation system, which with a basic oscillator, an amplifier connected to its output or filters connected to the outputs of the frequency dividers the outputs of the amplifiers connected to modulators or filters connected to the modulators, characterized in that at least two frequency dividers (Dl, Dll) are directly connected to the single basic oscillator (0), that fifteen outgoing frequency outputs (Fe, Fe ₂ , F _C4 , F _CIO ' ^F _V1 ) at least six frequency outputs are connected directly via an amplifier to the output of frequency dividers (D3, D7, D13, D4, D2, D14). 6. Circuit arrangement according to claim 5, characterized in that the output of the basic oscillator (0) branches in two directions: to the input of the frequency divider (D1) with a division ratio of 20: 1 and to the input of the frequency divider (D10) with one Division ratio of 7: 1, that the output of the frequency divider (D1) with a division ratio of 20: 1 with the input of the frequency divider (D2) with a division ratio of 7: 1 and the input of the frequency divider (D4) with a division ratio of 6: 1 is connected, while the frequency divider (Dll) with a division ratio of 7: 1 is connected to the input of the frequency divider (D13) with a division ratio of 16: 1 and the input of the frequency divider (D12) with a division ratio of 3: 1, whose output is routed to the input of the frequency divider (D6) with a divider ratio of 32: 1 and to the input of the frequency divider (D7) with a divider ratio of 5: 1, so that the output of the.frequ divider (D13) with a division ratio of 16: 1 is connected on the one hand to the channel carrier frequency output (F _C4 ) and on the other hand to the input of the frequency divider (D14) with a division ratio of 2: 1, the output of which is connected to the input of the amplifier (E8) is, the output of the amplifier (E8) forms the system carrier control frequency output (F _VI ) on the one hand and on the other hand to the input of the frequency divider (D15) a divider ratio of 2: 1 and to the input of the frequency divider (D16) with a divider ratio of 5: 1, furthermore the output of the frequency divider (D2) with a divider ratio of 7: 1 to the input of the frequency divider (D3) with a Divider ratio of 4: 1 and connected to the input of the amplifier (E2), while the output of the frequency divider (D3) is connected with a divider ratio of 4: 1 to the input of the amplifier (El) that the output of the frequency divider ( D4) with a division ratio of 6: 1 is connected to the input of the frequency divider (D5) with a division ratio of 4: 1 and to the input of the amplifier (E3), furthermore the output of the frequency divider (D5) with a division ratio of 4: 1 connected to the input of the amplifier (E5), while the output of the frequency divider (D7) is applied with a division ratio of 5: 1 to the input of the amplifier (E6), that the output of the Frequ divider (D15) with a division ratio of 2: 1 is connected to the input of the filter (SZ13), the output of which is connected to the input (a) of the modulator (Mll), while the output of the modulator (Mll) is connected to the filter ( SZ14) is connected, furthermore the output of the frequency divider (D16) is passed with a division ratio of 5: 1 to the input of the filter (SZ15), the output of which is connected to the input of the amplifier (E7), while the output of the amplifier ( E7) is led to the input (b) of the modulator (Mll), the output of the filter (SZ14) forming the system carrier output (F _FR ), that the output of the amplifier (E1) continues to the pre-modulation carrier frequency output (F _E ) and on the input (a) of the modulator (M1) and the input (a) of the modulator (M4) is connected so that the output of the amplifier (E2) to the channel carrier frequency output (F _C10 ) and to the inputs (b) of the modulators (M6 , M8), the exit of the Amplifier (E3) to the inputs (b) of the modulators (Ml, M2, M4) and to the channel carrier frequency output (F _C6 ), the output of the amplifier (E4) to the inputs (a) of the modulators (M2, M5, M6, M9), the output of the amplifier (E5) to the inputs (a) of the modulators (M3, M8), the output of the amplifier (E6) to the inputs (b) of the modulators (M3, M4, M5) and to the channel carrier frequency output (F _C2 ) are connected so that the output of the filter (SZ1) connected to the modulator (M1) continues to be the channel carrier frequency output (F _C12 ), the output of the filter (SZ2) connected to the modulator (M2) the channel carrier frequency output (F _C11 ) , the output of the filter (SZ3) following the modulator M3) the channel carrier frequency output (F _C9 ), the output of the filter following the modulator (M4) the channel carrier frequency output (F _C8 ), the output of the modulator (M5 ) connecting filter (SZ5) the channel carrier frequency output (F _C7 ), the off of the filter (SZ6) following the modulator (MZ6) the channel carrier frequency output (FC5), the output of the filter following the modulator (M8) (SZ8) the channel carrier frequency output ( _FC3 ) and the output of the filter following the modulator (M9) (SZ9) form the channel carrier frequency output ( ^F _C1 ). 7. A circuit arrangement for the generation of channel carrier frequencies, and system support control frequencies for vielkanälige carrier current telephone systems with Vormodulationssystem, with a basic oscillator, a to the output of the G _r undoszillators subsequent combination of frequency dividers to the output of the frequency divider subsequent amplifiers or to the output , is provided at the output of the amplifier connected to the output of modulator and connected filter of the frequency divider (D16) subsequent filter, characterized in that the G _r undoszillator (0) at least two pre quenzteilers (Dl, Dll) are directly connected, furthermore of seven outgoing frequency outputs at least six outputs (Fe, F _C4 , F _C6 , F _V1 , ^F _V2 , ^F _V3 ) via an amplifier (El) or filter (SZ12) directly to the Output of the frequency divider are connected. 8. Circuit arrangement according to claim 7, characterized in that the output of the basic oscillator (0) is connected to the input of the frequency divider (Dl) with a division ratio of 20: 1 and to the input of the frequency divider (Dll) with a division ratio of 7: 1 Furthermore, the output of the frequency divider (Dl) with a division ratio of 20: 1 is connected to the input of the frequency divider (D4) with a division ratio of 6: 1 and to the input of the frequency divider (D2) with a division ratio of 7: 1 , while the output of the frequency divider (D4) with a division ratio of 6: 1 forms the channel carrier frequency output (F _e6 ), that the output of the frequency divider (D2) with a division ratio of 7: 1 continues to the input of the amplifier (E2) and on the input of the frequency divider (D3) is connected with a divider ratio of 4: 1, the output of which is on the one hand to the system carrier control frequency output (F _V3 ) and on the other hand to the input of the verse tärkers (El) is guided, the output of which forms the pre-modulation carrier frequency output (F _E ), furthermore the output of the amplifier (E2) is connected to the input (b) of the modulator (M6), while the output of the frequency divider (Dll) is divided by a ratio of 7: 1 is connected to the input of the frequency divider (D12) with a division ratio of 3: 1 and to the input of the frequency divider (D13) with a division ratio of 16: 1, the output of which is on the one hand to the channel carrier frequency output (F _C4 ) and on the other is applied to the input of the filter (SZ12), the output of which forms the system carrier control frequency output (F _V1 ), that continues to be the output of the frequency divider (D12) with a division ratio of 3: 1 connect the input of the frequency divider (D6) with a division ratio of 32: 1 and the input of the frequency divider (D17) with a division ratio of 4: 1, while the output of the frequency divider (D16) with a division ratio of 32: 1 is connected to the input of the amplifier (E4), the output of which is led to the input (a) of the modulator (M6), that the output of the frequency divider (D17) continues to the system carrier control frequency output (F _V2 ) forms, furthermore the output of the modulator (M6) is connected to the input of the filter (SZ6), the output of the filter (SZ6) forming the channel carrier frequency output (F _CS ).

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